CN204428876U - MVR continuous evaporative crystallization system - Google Patents

Abstract

The utility model relates to MVR continuous evaporative crystallization system.This system comprises feed(raw material)inlet, moisturizing entrance, preheater, climbing film evaporator, gas-liquid separator, a compressor, pipeline heater, crystal separator and four control loops; Gas-liquid separator is provided with entrance, the first outlet, the second outlet and the 3rd outlet; Preheater connects climbing film evaporator by pipeline, and climbing film evaporator connects the entrance of gas-liquid separator; Compressor is connected between gas-liquid separator and climbing film evaporator by steam conveying pipe; Circulating evaporator is by being connected between the second outlet and entrance, and the cooling water after the cooling water after climbing film evaporator heat exchange and circulating evaporator heat exchange is as the thermal source of preheater, and the cooling water output of preheater and moisturizing entrance are jointly for giving system water supplement; Crystal separator connects the 3rd outlet on gas-liquid separator, and four control loops are located in said system, this systematic parameter is optimized and stablizes, and water saving, energy-conservation, joint raw material, crystallization effect is good.

Description

MVR continuous evaporative crystallization system

Technical field

The utility model belongs to evaporation and crystallization system, particularly relates to a kind of with energy-conservation and MVR continuous evaporative crystallization system that is water-saving result.

Background technology

Function of mechanical steam recompression Mechanical Vapor Recompression technology is a kind of high-efficient energy-saving environment friendly technology, is called for short MVR.Although disclose a lot of MVR continuous evaporative crystallization system adopting mechanical vapor recompression technology in prior art, just few in the application of technical grade.

Unreasonable due to technological design, a lot of function of mechanical steam recompression continuous evaporative crystallization system generally only has single-stage vapor compression machine to the heat supply of evaporimeter, in crystallizer part, material does not still carry out a large amount of heat supplies, cause the crystallization effect of existing function of mechanical steam recompression continuous evaporative crystallization system bad, the problem such as grain size number is tiny as occurred.Certainly, also there is part producer can increase jet chimney with supplementary crystalline portion heat supply, but considerably increase the complexity of MVR system, and rely on steam boiler, make MVR system without its original significant advantage-break away from dependence to steam boiler.

For these problems, publication number is disclose a kind of function of mechanical steam recompression continuous evaporative crystallization system of solving the problem and method in CN103203116A Chinese invention patent application prospectus, this function of mechanical steam recompression continuous evaporative crystallization system have employed two Mechanical Vapor Compression, and two compressors are respectively to evaporimeter and crystallizer heat supply, also one-level recovery has been carried out to cooling water sensible heat, for preheating, but this continuous evaporative crystallization system have employed two Mechanical Vapor Compression, the equipment cost buying two Mechanical Vapor Compression is very high, and do not have rational structure to be heated to bubble point temperature to material in advance, the energy consumption of therefore starting two compressors is also very high, structure is numerous and diverse, cause energy-saving effect also unsatisfactory.

In addition, existing MVR continuous evaporative crystallization system is except energy-conservation, recycling of few consideration water route, cause existing MVR continuous evaporative crystallization system continuous flow procedure can discharge many cooling waters, not only rationally do not recycle the heat energy of cooling water, prevent the pollution of cooling water, and new needs steam new in a large number fills into, waste water resource.

Finally, existing MVR continuous evaporative crystallization system is not all set up automatic control system and is gone to control its parameter, causes existing MVR continuous evaporative crystallization system optimization level low, affects the control of crystallization product and crystallization energy consumption.

Utility model content

Goal of the invention of the present utility model is to provide a kind of rational technology, and cost is low, and raw material, without waste, controls automatically, and continuity is good, and with better energy-conservation and MVR continuous evaporative crystallization system that is water-saving result.

In order to realize above-mentioned utility model object, the utility model have employed following technical scheme:

A kind of MVR continuous evaporative crystallization system, described system comprises feed(raw material)inlet, moisturizing entrance, preheater, climbing film evaporator, gas-liquid separator, function of mechanical steam recompression machine, forced-circulation evaporator, crystal separator, pipeline heater, feeding temperature control loop, a compressed steam control loop, fills into automatic steam control loop and gas-liquid separator liquid level control loop; Described preheater, climbing film evaporator and forced-circulation evaporator are all heat exchange units; Its include be connected material input, material output and the thermal source input be connected, cooling water output; Described gas-liquid separator comprise entrance for sending into gas-liquid mixed material, for export steam the first outlet, for feed liquid forced circulation the second outlet and send the 3rd outlet of crystallization for feed liquid; Described feed(raw material)inlet connects the material input of preheater by pipeline, and the material output of preheater connects the material input of climbing film evaporator by pipeline, the material output of climbing film evaporator connects the entrance of gas-liquid separator; Described function of mechanical steam recompression machine is connected between the first outlet of gas-liquid separator and the thermal source input of climbing film evaporator by steam conveying pipe, vapour pressure in order to be exported by described gas-liquid separator shortens superheated steam into and sends into climbing film evaporator, rises film heat to realize material; The material input of described forced-circulation evaporator connects the second outlet of gas-liquid separator, and the material output of forced-circulation evaporator is linked back the entrance of gas-liquid separator; The thermal source input of forced-circulation evaporator connects the superheated steam output directly connecting the compression of function of mechanical steam recompression machine; The cooling water output of described climbing film evaporator and forced-circulation evaporator is connected by pipeline and cooling water is sent into the thermal source input of preheater, in order to the material supplementary heating flowed through in preheater; The cooling water output of described preheater and moisturizing entrance remittance merga pass pipeline heater are connected into the compressed steam pipeline after function of mechanical steam recompression machine output; Described crystal separator connects the 3rd outlet on described gas-liquid separator;

Described in i, feeding temperature control loop comprises:

-electric heater between feed(raw material)inlet and preheater;

-first flow control valve between feed(raw material)inlet and electric heater;

-the first temperature measuring unit between preheater and climbing film evaporator; With

-the first temperature controller;

Described first temperature measuring unit signal connects the first temperature controller, and the first temperature controller output divides level signal to connect electric heater and first flow control valve;

Described in ii, compressed steam control loop comprises:

-be positioned at function of mechanical steam recompression machine after, the second temperature measuring unit before climbing film evaporator thermal source input;

-the second temperature controller; And

-frequency converter

Described second temperature measuring unit signal connects the second temperature controller; Second temperature controller connects function of mechanical steam recompression machine, to control the compression horsepower of function of mechanical steam recompression machine by frequency converter;

Fill into automatic steam control loop described in iii to comprise:

-be arranged on the second control valve of moisturizing entrance output;

-be installed on pipeline heater after, the 3rd temperature measuring unit before being connected into compressed steam pipeline;

-be installed on the 3rd temperature measuring unit after, the 3rd flow control valve before being connected into compressed steam pipeline;

-be installed on the 4th temperature measuring unit of climbing film evaporator material output; And

-three temperature controller;

Described 3rd temperature measuring unit, the 4th temperature measuring unit divide level signal to connect the input of the 3rd temperature controller; The output of described 3rd temperature controller connects and control valve channel heater, second control valve and the 3rd flow control valve respectively.

Described in iiii, gas-liquid separator liquid level control loop comprises:

-be arranged on liquid level gauge on gas-liquid separator;

-fluid level controller; With

-be arranged on gas-liquid separator second to export the 4th flow control valve between forced-circulation evaporator material input;

Described liquid level gauge signal connecting fluid level controller, fluid level controller signal connects and controls the 4th flow control valve.

As preferred version of the present utility model:

Described crystal separator comprises the 3rd entrance exported, crystallize out delivery outlet and the feed liquid delivery outlet that connect on described gas-liquid separator, and described feed liquid delivery outlet is connected into the material input of described forced-circulation evaporator.

As further improvement of the utility model scheme:

Also comprise surge tank and cooling water conveying pump; Surge tank and cooling water conveying pump are located on the pipeline before the thermal source input of preheater successively; Described climbing film evaporator is connected preheater by surge tank with cooling water conveying pump all successively with the cooling water output of forced-circulation evaporator.

As further improvement of the utility model scheme:

Pipeline between second outlet of described gas-liquid separator and the material input of forced-circulation evaporator is provided with forced circulation pump.

As further improvement project of the present utility model:

The feed liquid delivery outlet of described crystal separator is connected into the material input of forced-circulation evaporator by forced circulation pump; Described 4th flow control valve is between forced circulation pump and forced-circulation evaporator material input.

Have employed the MVR continuous evaporative crystallization system of technique scheme, there is following beneficial effect:

One, this system only adopts single Mechanical Vapor Compression, with more existing adopt compared with the continuous evaporative crystallization device of mechanical vapor recompression technology, the Mechanical Vapor Compression of its default unit price costliness, cost is low.

Two, this system only MVR continuous evaporative crystallization system of setting up of single Mechanical Vapor Compression, also multistage recovery indirect steam being carried out to energy can be achieved, the sensible heat of final withdrawal indirect steam and latent heat, and gas-liquid separator is entered to material and crystal separator carries out level forced circulation, also the heat of indirect steam is taken full advantage of in forced circulation, very energy-conservation, and it utilizes forced circulation to gas-liquid separator even crystal separator Feedback heat, make up the short slab that crystal separator lacks heating, thus improve crystalline rate and effect.

Three, in system of the present utility model, the cooling water of finally discharging in preheater is supplemented by by the water resource of MVR continuous evaporative crystallization system as moisturizing porch again, thus farthest reuse heat and water.

Four, of the present utility modelly multi-point automatic control system is established, control the key parameter of whole system, so, this system is not only farthest made to make energy saving optimizing, stable state is entered fast when MVR continuous evaporative crystallization system can also be allowed just to start, therefore interval shutdown process energy loss is few, thus crystalline quality is able to stability contorting.In addition, the foundation of automatic control system also makes technique suddenly change can self-adaptative adjustment, and process disturbance is few, thus makes MVR continuous evaporative crystallization system continuity good, more energy-conservation and water saving.

In sum, the MVR continuous evaporative crystallization system not only rational technology that the utility model provides, and it is cheap to build the equipment cost religion that this MVR continuous evaporative crystallization system adopts, and realizes water, material and heat energy without waste, automatic control, process stabilizing, interference is few, is beneficial to consecutive production, continuous crystallisation quality control is out consistent, reach well energy-conservation, water-saving result simultaneously, only need to mend a small amount of water, zero pollutant discharge.

Accompanying drawing explanation

Fig. 1: the process flow diagram of MVR continuous evaporative crystallization system in the utility model embodiment.

Detailed description of the invention

Below in conjunction with accompanying drawing, the utility model is described further.

Embodiment 1:

A kind of MVR continuous evaporative crystallization system as shown in Figure 1, this system is primarily of feed(raw material)inlet 1a, moisturizing entrance 1b, preheater 2, climbing film evaporator 3, gas-liquid separator 4, function of mechanical steam recompression machine 5, forced-circulation evaporator 7, pipeline heater 12, crystal separator 6, surge tank 13, forced circulation pump 10, cooling water conveying pump and four automatic control loop compositions on this system.Four automatic control loops are feeding temperature control loop respectively, compressed steam control loop, fill into automatic steam control loop and gas-liquid separator liquid level control loop

Above-mentioned band preheater 2, climbing film evaporator 3 and forced-circulation evaporator 7 mainly through heat exchange mode to the heating material flow in it, therefore, its structure is heat exchange unit, and it all has the material input flowed into for material, flows through in it material output having flowed out heating or evaporation; Also there is the thermal source input and cooling water output, totally four ports that flow into thermal source.As in Fig. 1, Reference numeral is specific as follows: the material input 20 of preheater, the material output 21 of preheater, the thermal source input 22 of preheater and the cooling water output 23 of preheater; The material input 30 of climbing film evaporator, the material output 31 of climbing film evaporator, the thermal source input 32 of climbing film evaporator and the cooling water output 33 of climbing film evaporator; The cooling water output 73 of the material input 70 of forced-circulation evaporator, the material output 71 of forced-circulation evaporator, forced-circulation evaporator thermal source input 72 and forced-circulation evaporator.

And the top of above-mentioned gas-liquid separator 4 is provided with the entrance 40 for sending into gas-liquid mixture and the first outlet 41 for exporting steam, the bottom of gas-liquid separator 4 be provided with for feed liquid forced circulation the second outlet 42 and send the 3rd outlet 43 of crystallization for feed liquid, air filter formula screen pack 44 is provided with on the entrance 40 of gas-liquid separator 4 and on the gas-liquid separator 4 of the upper/lower positions of the first outlet 41, air filter formula screen pack 44 is that a stratum reticulare is high between 80-150mm, the silk screen of order number between 300-500 order, and air filter formula screen pack 44 outward flange is connected with gas-liquid separator 4 inner wall sealing, upper and lower two chambers will be divided in gas-liquid separator 4.

After describing above-mentioned several equipment, we describe the MVR continuous evaporative crystallization system without building automatic control loop, and concrete system syndeton is as follows:

As shown in Figure 1, above-mentioned raw materials entrance 1a connects the material input 20 of preheater 2 by pipeline, pipeline drives its feeding preheater 2 by feeding engine 9, material output 21 pipeline of preheater 2 connects the material input 30 bottom climbing film evaporator 3, material carries out climbing-film evaporation after flowing to climbing film evaporator 3, spray from the material output 31 of climbing film evaporator 3, climbing film evaporator 3 material output 31 connects the entrance 40 on above-mentioned gas-liquid separator 4 again.Then, the feed liquid of sending of gas-liquid separator 4 connects the entrance 60 of crystal separator 6 for the 3rd outlet 43 of crystallization by pipeline, crystal separator 6 is also provided with crystallize out delivery outlet 61 and feed liquid delivery outlet 62, the crystallize out delivery outlet 61 of crystal separator 6 connects the holding tank 8 below it.

As shown in Figure 1, on the other hand, above-mentioned gas-liquid separator 4 pairs of materials have carried out gas-liquid separation, for exporting the input of the first outlet 41 by steam conveying pipe connection Mechanical Vapor Compression 5 of steam in gas-liquid separator 4.The output of Mechanical Vapor Compression 5 is connected into the thermal source input 32 of climbing film evaporator 3 by steam conveying pipe, the superheated steam shortened in order to the vapour pressure first of gas-liquid separator the outlet 41 exported also sends into climbing film evaporator 3, become hot water by steam-condensation and hot water cooling method release latent heat and sensible heat again, in climbing film evaporator 3, rise film heat to realize material.

In addition, system of the present utility model also has two-stage forced circulation, as shown in Figure 1, above-mentioned forced-circulation evaporator 7 is connected between the second outlet 42 of gas-liquid separator 4 and the entrance 40 of gas-liquid separator by pipeline, specifically the material input 70 of forced-circulation evaporator 7 exports 42 with second of gas-liquid separator 4 and is connected, the material output 71 of forced-circulation evaporator 7 is linked back by pipeline the entrance 40 of gas-liquid separator, above-mentioned forced circulation pump 10 is located on the pipeline between the second outlet 42 of gas-liquid separator and the material input 70 of forced-circulation evaporator 7, this is forced-circulation evaporator 7 pairs of gas-liquid separator first order forced circulation.The feed liquid delivery outlet 62 of crystal separator 6 is also connected into the material input 70 of forced-circulation evaporator 7 by forced circulation pump 10, this is the second level forced circulation of forced-circulation evaporator 7 pairs of crystal separators 6.And the thermal source input 72 of forced-circulation evaporator 7 connects the superheated steam output directly connecting function of mechanical steam recompression machine 5 and compress.

Most importantly, the utility model also uses the hot water of climbing film evaporator 4 cooling water output 33 and the output of forced-circulation evaporator 7 cooling water output 73, utilize the obvious of these hot water further, namely the thermal source input 22 of preheater 2 is connected by pipeline, in order to the material supplementary heating flowed through in preheater 2, thus energy-conservation further.Particularly, in order to prevent, hot water is excessive to be poured, and above-mentioned surge tank 13 and cooling water conveying pump are located on the pipeline before the thermal source input 22 of preheater 2 successively.Therefore, the cooling water output 33 of climbing film evaporator is connected preheater 2 by surge tank 13 with cooling water conveying pump in fact all successively with the cooling water output 73 of forced-circulation evaporator.

Finally, as shown in Figure 1, the cooling water output 23 of above-mentioned preheater 2 and moisturizing entrance 1b are connected into the compressed steam pipeline after function of mechanical steam recompression machine 5 output by pipeline heater 12.

In fact, the power dissipation ratio that every platform Mechanical Vapor Compression 5 uses is larger, if material is not heated to bubble point temperature in preheater 2, finally can affect rear film of continuing rising heat and compressor to the total power consumption of the recompression process of steam, the total energy consumption of whole continuous crystallisation device can be increased, but in order to ensure good energy saving technology effect, depend merely on the preheater 2 sometimes pre-heating temperature elevation deficiency of cooling water as thermal source, therefore in order to control the temperature of charge of the utility model at preheater 2 output, the utility model has set up above-mentioned feeding temperature control loop herein, one ensures that the temperature of charge of preheater 2 output is able to constant.

As shown in Figure 1, feeding temperature control loop specifically comprises electric heater 11, first flow control valve 90, first temperature measuring unit 101 and the first temperature controller 1010; Wherein the first temperature measuring unit 101 is arranged on the material pipe between preheater 2 and climbing film evaporator 3, is namely arranged on preheater 2 output or its material pipe extension to climbing film evaporator 3 material input 30.Electric heater 11 is arranged on the material pipe between feed(raw material)inlet 1a and preheater 2, preferably after feeding engine 9.First flow control valve 90 is arranged on the material pipe between feeding engine 9 and preheater 2.First temperature measuring unit 101 signal connects the first temperature controller 1010, first temperature measuring unit 101 and inputs the first temperature controller 1010 and be analyzed, and the first temperature controller 1010 output divides level signal to connect electric heater 11 and first flow control valve 90.Here, when system starts, general first flow control valve 90 standard-sized sheet, preferentially carrys out the temperature that FEEDBACK CONTROL first temperature measuring unit 101 detects reach setting value bubble point temperature by controlling electric heater 11.During system stalls, general first closedown function of mechanical steam recompression machine 5, now the heating efficiency of preheater 2 is corresponding weakens, and the first temperature controller 1010 priority acccess control first flow control valve 90 controls mass flow, thus ensure system stalls time last batch of crystalline quality.To this, the first temperature controller 1010 need only the priority of automatic spacing setting in advance.

In order to control crystalline quality well, ensureing the parameter stability of each heat exchange unit in whole system, controlling the temperature and pressure of compressed steam well, just must control function of mechanical steam recompression machine 5 power.Therefore, native system also introduces above-mentioned compressed steam control loop around function of mechanical steam recompression machine 5, this control loop specifically comprises the second temperature measuring unit 102, second temperature controller 1020 and frequency converter 1021, after wherein the second temperature measuring unit 102 is installed on function of mechanical steam recompression machine 5, on the compressed steam pipeline before climbing film evaporator 3 thermal source input 32.Second temperature measuring unit 102 signal connects the second temperature controller 1020, and the temperature signal collected sends into the second temperature controller 1020, with analysis of making comparisons in optimized setting value; Second temperature controller 1020 connects function of mechanical steam recompression machine 5 by frequency converter 1021, is changed the size of function of mechanical steam recompression machine 5 input voltage or electric current by frequency converter 1021, to control the compression horsepower of function of mechanical steam recompression machine 5.

System of the present utility model, except fully reclaiming the heat energy produced in evaporation and crystal process, also fully take into account the utility model in system links likely loss water resource, therefore, system of the present utility model needs very long moisturizing or steam course in operation early stage.Consider in the utility model technique, the steam needed most directly utilizing is supplied, the utility model fills into automatic steam control loop in the cooling water output reuse of preheater 2 to introducing between compressed steam pipeline, and it specifically comprises second control valve 1032, the 3rd temperature measuring unit 103, the 3rd flow control valve 1033, the 4th temperature measuring unit 104 and the 3rd temperature controller 1030; Wherein, second control valve 1032 is arranged on moisturizing entrance 1b output; 3rd temperature measuring unit 103 is installed on the pipeline after pipeline heater 12, and be connected into the node of compressed steam pipeline at this pipeline before; After 3rd flow control valve 1033 is installed on the 3rd temperature measuring unit 103, before above-mentioned node; 4th temperature measuring unit 104 is installed on climbing film evaporator 3 material output 31, the actual controller becoming two cover control loops of the 3rd temperature controller 1030 here.On physical couplings, the 3rd temperature measuring unit 103, the 4th temperature measuring unit 104 points of level signals connect the input of the 3rd temperature controller 1030; The output of the 3rd temperature controller 1030 connects and control valve channel heater 12, second control valve 1032 and the 3rd flow control valve 1033 respectively.3rd temperature controller 1030 needs, according to the 3rd temperature measuring unit 103, to guarantee that the water in pipeline is heated into steam, and inputs the 3rd temperature controller 1030, carrys out the heating power of control valve channel heater 12.On tangible, only maximum heating power still can not meet temperature that the 3rd temperature measuring unit 103 surveys reach setting value time, the 3rd temperature controller 1030 just enters second priority level to control second control valve 1032, reduces the water yield.And from the 4th temperature measuring unit 104 collection signal input the 3rd temperature controller 1030, control the 3rd flow control valve 1033 again and carry out feedback regulation, be only a shared controller between the above-mentioned another set of loop of this loop and the 3rd temperature controller 1030, there is no priority relationship.

Gas-liquid separator liquid level control loop, its object arranged is very direct, exactly in order to control the proportion of forced circulation in gas-liquid separator, therefore, optimizes the energy consumption being directly involved in crystalline quality and whole system herein.Certainly, when forced circulation proportion is very big, the energy consumption of whole system is increase on foot, and crystalline rate is low, and crystalline quality can increase.And forced circulation proportion is when being less than a threshold value, crystalline rate remains on necessarily high constant level, but crystalline quality can reduce.Therefore the liquid level of gas-liquid separator will keep more accurate, a more constant parameter as well.Introduce gas-liquid separator liquid level control loop, it comprises:

-be arranged on liquid level gauge 101L on gas-liquid separator;

-fluid level controller 1010L; With

-be arranged on gas-liquid separator second to export the 4th flow control valve 100 between 42 and forced-circulation evaporator material input 70;

Above-mentioned liquid level gauge 101L signal connecting fluid level controller 1010L, fluid level controller 1010L signal connects and the aperture controlling the 4th flow control valve the 100, four flow control valve 100 directly affects the entrance of gas-liquid separator 4, thus affects its liquid level.

As fully visible, the utility model adopts a Mechanical Vapor Compression 5 pairs of climbing film evaporators 3 and forced-circulation evaporator 7 together steam heating, respectively climbing film evaporator 3 and forced-circulation evaporator 7 are distinguished to the equipment of heat supply than employing two Mechanical Vapor Compression 5, at least energy-conservation more than 20%.Why adopt a Mechanical Vapor Compression 5 just can realize above-mentioned heat supply, one of reason is also that combining the utility model have employed and by the preheater 2 of heating material to bubble point temperature, thus can reduce the operating pressure of single Mechanical Vapor Compression 5.Consider that Mechanical Vapor Compression 5 is expensive, in the continuous evaporative crystallization equipment of existing employing mechanical vapor recompression technology, the price of Mechanical Vapor Compression 5 accounts for complete equipment price 30-50%, therefore taking cost into account, continuous evaporative crystallization device of the present utility model has the two-fold advantage that cost is low and energy consumption is low concurrently.

In addition, the utility model introduces four control loops, namely excellent control system is established to whole MVR continuous evaporative crystallization system, there is control system, it is constantly got rid of, reduce interference to systematic parameter, optimize whole system parameter, improve the stability of whole system, and further reduce its energy consumption.

The above-mentioned Mechanical Vapor Compression 5 of the present embodiment is Roots Compressor, and above-mentioned climbing film evaporator 3 is pipe heat exchangers.

It should be noted that the utility model to the utilization of cooling water depending on steam loss situation, when complete equipment steam loss situation is comparatively large, the cooling water in the water of moisturizing entrance 1b and the cooling water output 23 of preheater 2 all accesses; When complete equipment steam loss situation is less, the cooling water in the cooling water output of preheater all accesses; When complete equipment steam loss situation is less, also likely part cooling water drainage is bled off, part access.

Following is the method adopting the utility model MVR continuous evaporative crystallization system to carry out continuous crystallisation, comprises the steps:

A. first, sent into by material feeding to be crystallized in preheater 2, the sensible heat passing through above-mentioned cooling water in preheater, as thermal source, by heating material to its bubble point temperature, but does not produce the hot solution of steam;

B. the hot solution in step a is sent in climbing film evaporator 3, superheated steam after climbing film evaporator 3 is compressed by Mechanical Vapor Compression 5 is as using, heat exchange is carried out to above-mentioned hot solution material, realize rising film heating, and producing a large amount of indirect steams, solution is brought into gas-liquid separator 7 by indirect steam together.

In this step, employing climbing film evaporator 3 is that the advantage of pipe heat exchanger is as follows: first, the expense of pipe heat exchanger unit volume is minimum in current evaporimeter, secondly, compared with other evaporimeters, pipe heat exchanger structure is more simple, and making and installation requires relatively low, finally, in the heat-transfer pipe of pipe heat exchanger, the flow velocity of indirect steam is quite fast, and between usual 20m/s-50m/s, the feed liquid time of staying is short, but total heat exchange system is still larger, generally can reach 1200 ~ 6009w/m ²h DEG C.

The indirect steam that wherein solution is brought into gas-liquid separator 4 process by indirect steam together sprays into speed between 25 ~ 50m/s, in order to prevent indirect steam short circuit, during work, the air filter formula screen pack installed in above-mentioned gas-liquid separator 4 forms one mist eliminating barrier, the liquid foam gear carried secretly by the indirect steam that material evaporation produces goes back, and only has indirect steam to pass through.

Consider that indirect steam sprays into speed between 25 ~ 50m/s, speed quickly, therefore we to have employed stratum reticulare high between 80-150mm, the silk screen of order number between 300-500 is as air filter formula screen pack, silk screen is to the mist of particle diameter >=3 ~ 5um, arresting efficiency reaches 97%-98.9%, and effect is very good.

C. be separated through gas-liquid separator 4, a concentrated solution part exports 42 by gas-liquid separator 4 second and again sends into forced-circulation evaporator 7 heating evaporation, and the gas-liquid mixture of generation returns to gas-liquid separator 4; Another part is from being expelled to crystal separator crystallization 6; In this step, indirect steam is sent gas-liquid separator and is compressed into superheated steam by function of mechanical steam recompression machine, then sends into climbing film evaporator 3 and forced-circulation evaporator 7 as heating energy source; Cooling water is sent into the part heating energy source of preheater 2 as pre-heater by the cooling water output of climbing film evaporator 3 and forced-circulation evaporator 7.Cooling water and the moisturizing entrance 1b of the cooling water output eliminating of preheater collect jointly, and are connected into the compressed steam pipeline after function of mechanical steam recompression machine 5 output by pipeline heater 12.By the multistage recycling of heat energy of this steam and water, adopt the continuous evaporative crystallization method of said system, not only continuous seepage is effective, and waste without raw material, water, cost is low, but also very energy-conservation.

D. in separator crystallization 6, crystallize out is discharged, and residue concentrated solution also delivers to heating evaporation in the forced-circulation evaporator 7 in step c.

Embodiment 2:

Embodiment 2 is with the difference of embodiment 1, and the Mechanical Vapor Compression 5 of the present embodiment is centrifugal compressor, and all the other repeat embodiment 1.

Claims (5)

1.MVR continuous evaporative crystallization system, is characterized in that:

Described system comprises feed(raw material)inlet (1a), moisturizing entrance (1b), preheater (2), climbing film evaporator (3), gas-liquid separator (4), function of mechanical steam recompression machine (5), forced-circulation evaporator (7), crystal separator (6), pipeline heater (12), feeding temperature control loop, a compressed steam control loop, fills into automatic steam control loop and gas-liquid separator liquid level control loop;

Described preheater (2), climbing film evaporator (3) and forced-circulation evaporator (7) are all heat exchange units; Its include be connected material input (20,30,70), material output (21,31,71) and the thermal source input (22,32,72) be connected, cooling water output (23,33,73);

Described gas-liquid separator (4) comprise entrance (40) for sending into gas-liquid mixed material, for export steam the first outlet (41), for feed liquid forced circulation the second outlet (42) and send the 3rd outlet (43) of crystallization for feed liquid;

Described feed(raw material)inlet (1a) connects the material input (20) of preheater (2) by pipeline, the material output (21) of preheater (2) connects the material input (30) of climbing film evaporator (3) by pipeline, the material output (31) of climbing film evaporator (3) connects the entrance (40) of gas-liquid separator;

Described function of mechanical steam recompression machine (5) is connected between the first outlet (41) of gas-liquid separator (4) and the thermal source input (32) of climbing film evaporator by steam conveying pipe, vapour pressure in order to be exported by described gas-liquid separator shortens superheated steam into and sends into climbing film evaporator, rises film heat to realize material;

The material input (70) of described forced-circulation evaporator (7) connects the second outlet (42) of gas-liquid separator, and the material output (71) of forced-circulation evaporator (7) is linked back the entrance (40) of gas-liquid separator; The direct compressed steam output connecting function of mechanical steam recompression machine (5) and compress of the thermal source input (72) of forced-circulation evaporator (7);

The cooling water output (33,73) of described climbing film evaporator (3) and forced-circulation evaporator (7) is connected by pipeline and cooling water is sent into the thermal source input (22) of preheater (2), in order to the material supplementary heating flowed through in preheater (2);

The cooling water output (23) of described preheater (2) and moisturizing entrance (1b) converge merga pass pipeline heater (12) and are connected into compressed steam pipeline after function of mechanical steam recompression machine (5) output;

Described crystal separator (6) connects the 3rd outlet (43) on described gas-liquid separator (4);

Described in i, feeding temperature control loop comprises:

-be positioned at electric heater (11) between feed(raw material)inlet (1a) and preheater (2);

-be positioned at first flow control valve (90) between feed(raw material)inlet (1a) and electric heater (11);

-be positioned at the first temperature measuring unit (101) between preheater (2) and climbing film evaporator (3); With

-the first temperature controller (1010);

Described first temperature measuring unit (101) signal connects the first temperature controller (1010), and the first temperature controller (1010) output divides level signal to connect electric heater (11) and first flow control valve (90);

Described in ii, compressed steam control loop comprises:

-be positioned at function of mechanical steam recompression machine (5) after, the second temperature measuring unit (102) before climbing film evaporator (3) thermal source input (32);

-the second temperature controller (1020); And

-frequency converter (1021)

Described second temperature measuring unit (102) signal connects the second temperature controller (1020); Second temperature controller (1020) connects function of mechanical steam recompression machine (5), to control the compression horsepower of function of mechanical steam recompression machine (5) by frequency converter (1021);

Fill into automatic steam control loop described in iii to comprise:

-be arranged on the second control valve (1032) of moisturizing entrance (1b) output;

-be installed on pipeline heater (12) after, the 3rd temperature measuring unit (103) before being connected into compressed steam pipeline;

-be installed on the 3rd temperature measuring unit (103) after, the 3rd flow control valve (1033) before being connected into compressed steam pipeline;

-be installed on the 4th temperature measuring unit (104) of climbing film evaporator (3) material output (31); And

-three temperature controller (1030);

Described 3rd temperature measuring unit (103), the 4th temperature measuring unit (104) point level signal connects the input of the 3rd temperature controller (1030); The output of described 3rd temperature controller (1030) connects and control valve channel heater (12), second control valve (1032) and the 3rd flow control valve (1033) respectively;

Described in iiii, gas-liquid separator liquid level control loop comprises:

-be arranged on liquid level gauge (101L) on gas-liquid separator;

-fluid level controller (1010L) and

-be arranged on gas-liquid separator second to export the 4th flow control valve (100) between (42) and forced-circulation evaporator material input (70);

Described liquid level gauge (101L) signal connecting fluid level controller (1010L), fluid level controller (1010L) signal connects and controls the 4th flow control valve (100).

2. MVR continuous evaporative crystallization system according to claim 1, is characterized in that:

Described crystal separator (6) comprises the entrance (60) of the 3rd outlet (43) connected on described gas-liquid separator (4), crystallize out delivery outlet (61) and feed liquid delivery outlet (62), and described feed liquid delivery outlet (62) is connected into the material input (70) of described forced-circulation evaporator (7).

3. MVR continuous evaporative crystallization system according to claim 1, is characterized in that:

Also comprise surge tank (13) and cooling water conveying pump; Surge tank (13) and cooling water conveying pump are located on the pipeline before the thermal source input (22) of preheater (2) successively; Described climbing film evaporator (3) is connected preheater (2) by surge tank (13) with cooling water conveying pump all successively with the cooling water output (33,73) of forced-circulation evaporator (7).

4. MVR continuous evaporative crystallization system according to claim 1, is characterized in that:

Pipeline between second outlet (42) of described gas-liquid separator and the material input (70) of forced-circulation evaporator (7) is provided with forced circulation pump (10).

5. MVR continuous evaporative crystallization system according to claim 2, is characterized in that:

Pipeline between second outlet (42) of described gas-liquid separator and the material input (70) of forced-circulation evaporator (7) is provided with forced circulation pump (10), and the feed liquid delivery outlet (62) of described crystal separator (6) is connected into the material input (70) of forced-circulation evaporator (7) by forced circulation pump (10); Described 4th flow control valve (100) is positioned between forced circulation pump (10) and forced-circulation evaporator material input (70).